US2402415A - Absorption refrigerating apparatus - Google Patents

Absorption refrigerating apparatus Download PDF

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US2402415A
US2402415A US475334A US47533443A US2402415A US 2402415 A US2402415 A US 2402415A US 475334 A US475334 A US 475334A US 47533443 A US47533443 A US 47533443A US 2402415 A US2402415 A US 2402415A
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pump
absorption
solution
heat
conduit
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US475334A
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Kogel Wilhelm Georg
Widell Nils Erik
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B15/00Sorption machines, plants or systems, operating continuously, e.g. absorption type
    • F25B15/10Sorption machines, plants or systems, operating continuously, e.g. absorption type with inert gas
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A30/00Adapting or protecting infrastructure or their operation
    • Y02A30/27Relating to heating, ventilation or air conditioning [HVAC] technologies
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/62Absorption based systems

Definitions

  • This invention relate to absorption refrigerating apparatus of the continuous cycle inert gas type including a gas bubble pump adapted during normal operation to efiect continuous circulation of absorption solution through the boiler and absorber.
  • the object of this invention is to provide a" method of and means for controlling the'operation of an absorption system of the above type.
  • the apps-- ratus includes an auxiliary liquid circulatin pump operable at will and adapted to convey absorption solution intended for-purposes other than absorption and in particular for effecting controlling operations during operation of said apparatus.
  • the invention includes a method of controlling the operation of absorption apparatus of the
  • the invention will be hereinafter more 'fully described with reference to the accompanying drawing illustrating several embodiments or the invention'by way of example and in which:
  • Fig. l shows diagrammatically an absorption U refrigerating apparatus having a pump operative accordim to the invention
  • Fig. .2 shows a diflerent means for starting the auxiliary pump.
  • Fig. 1, III designates the heating tube or flue of an absorption refrigerating apparatus working for example with water, hydrogen and ammonia.
  • the upper part 01' the evaporator. in the usual manner is formed as a room cooler and is provided with cooling line.
  • lower coiled part serves for low temperature cooling suchasice-making.
  • the gas mixture evolved in the evaporator passes through a gas heat exchanger l8, a conduit 28, to an absorber vessel and thence up- 56 v 10 Claims.
  • -(Cl. 62-5) I 2 wardly through the, coil absorber IS in the usual manner back to the evaporator.
  • Connected to the condenser i4 and the gas heat exchanger I8 is the usual pressure vessel 2
  • the solution degasifled in the boiler flows to the absorber coil I! through a liquid heat exchanger 22 and a conduit 86 andpasses from the absorber vessel 20 through the inner tube of the heat exchanger 22 to a pump tube.
  • This pump is arrangedinheat-conductive connection 'with the heating tube so by spot welding points 8L.
  • an auxiliary pum'p conduit 40 communicating for example with the lower part of, the boiler conduit I l.
  • the pump conduit 40 terminates at its upper end in the pressure vessel 2!. This pump pumps the hot liquid from the boiler into the pressure vessel 2
  • the auxiliary pump 40 is heated by a heat transfer system,
  • This system consists of a collector 80 and a flexible tube 8
  • the rising leg or the U-tube 84 is. at 86, connected with the pump 40, and enters at 81 into the wide tube
  • the collector is filled with a heattransferring agent ofa suitable kind.
  • this collector When this collector is raised, its content will flow through the flexible connection 8i into the wide tube 88 and into the 'U-tube 84.
  • the liquid owing to the heating zone 85 will boil or possibly be pumped upwardly so that the heat of the heating tube through condensation or the hot pumped solution will'be transferred at the contact zone 86 to the pump 40 which will thus be set in op eration. Since the heat transfer system, except 'for the collector and the flexible conduit 8
  • vapours evolved at the contact point 85 will gradually condense at the coldest part 80 so that the system gradually boils dry due to collection of the transfer agent in the collector 80.
  • the system contains only vapour which insulates the pump 40 so that the heat transfer by conduction from the point 85 through the tube 84 to the point 86 is so small as to prevent further vapour expulsion in the
  • an agent is preferably chca'za which has a working pressure as low as possible relatively to that of the refrigerating apparatus.
  • the starting of the pump 40 for defrosting action is in this case particularly simple,
  • the operation of the pump 40 and therewith the defrosting process will cease automatically.
  • the collector 80 for example-by increasing its surface by means of fins orother cooling elements, it is possible to hasten the initial condensation therein, thus also shortening the defrosting process. This will enable control to be effected without regulating devices, valves or other sensitive elements as hitherto used.
  • the collector 80 may obviously be raised either manually or thermostatically, if desired through the intermediary of spring devices,
  • Fig. 2 shows another embodiment including an auxiliaryheat transfer system.
  • the pump 40 is led through the interior of the auxiliary system which consists of a wide tube 90 in heat-conductive connection at 9i withthe heating tube ID.
  • the collector 80 is connected to the wide tube 90 by means of the flexible conduit 8
  • Absorption type refrigerating apparatus having a circuit for absorption liquid, a circulator for causing flow of absorption liquid in said circuit, a heat operated pump for raising absorption liquid upward in said system above said circuit, a source of heat, and an evaporating-condensin system constructed and arranged to transfer heat from said source to said pump.
  • said evaporating-condensing system includes a conduit connected between the evaporating and condensing parts of the system and so constructed and arranged that liquid is caused to flow therethrough by vapor formed in said evaporating part, said conduit being'in heat transfer relation with said heat operated pump.
  • an aqueous solution of an anti-corrosive agent may be used, such as chromic acid alkaline salts. This will result in a relatively short heat-transfer period. If the system, however, contains aniline, for example, this will give long transfer periods. Also benzene, toluene, xylene and other cyclic hydrocarbons as well as many aliphatic hydrocarbons may be used as filling agents.
  • a heat transfer system of the evaporatingcondensing p which include a vapourislng element in heat conductive relation with a rela-' tively hot zone, a higher located heat dissipating element in heat conductive relation with a relatively cold zone and a condensing member 10-" cated above the heat dissipating element.
  • a heat transfer system of the evaporatingcondensing type comprising a riser conduit adapted for vapour lift action and having a lower heat absorbing and a higher heat delivering portion, a conduit of larger cross sectional area connected to opposite ends of the riser conduit and a consel, and said evaporating-condensing system is enclosed by thermal insulation, said vessel being located outside of said insulation.
  • An absorption refrigerating system includin a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift pump in said first solution circuit for lifting absorption solution to a point from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and said evaporator, a second vapor lift pump for lifting hot absorption solution from said second solution circuit to a point from whence said hot absorption solution flows by gravity into said evaporator, and a secondary heat transfer system associated with said generator for heating said second vapor lift pump.
  • An absorption refrigerating system includ-- ing a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift heating said second vapor lift pump, and means.
  • An absorption refrigerating system having a first solution circuit including a generator and an absorber, a vapor lift pump in said first solution circuit for lifting absorption solution into a part of said generator from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and an evaporator, a second vapor lift pump for lifting hot absorption solution in said second solution circuit to a point from whence said hot absorption solution ilows by gravity into said evaporator, a
  • secondary heat transfer system charged with avolatile fluid and having a heat receiving part associated with said generator, a heat transfer part associated with said second vapor lift pump, and a condensing part for storing said volatile fluid, the construction and arrangement of said secondary heat transfer system being such that said system is manually initiated and is autov matically stopped by collecting said volatile fluid in said condensing part.
  • An absorption refrigerating system including a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift pump in said first solution circuit for lifting absorption solution into. a part of said generator from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and said evaporator, a second vapor lift pump in said second solution circuit for liftchamber, said fluid collecting chamber being arranged to collect substantially all of thevolatile fluid contained in said secondary heat transfer system to thereby render said system ineffective as a heat transfer system.

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Mechanical Engineering (AREA)
  • Thermal Sciences (AREA)
  • General Engineering & Computer Science (AREA)
  • Sorption Type Refrigeration Machines (AREA)

Description

June 18, 1946. w. G. K6GEL' ET-AL 2,402,415
ABSORPTION REFRIGERATING APPARATUS Filed Feb. 10. 1943 INVENTO R5 Mum-2 6:090 #0454 A? fem lV/ae'u.
rerentedlu e l8,
UNITED STATES. PATENT orries- ABSORPTION ammnna'rmcarrmrus Wilhelm Georg Kiigel andNils Erik Widell,
Stockholm, Sweden.
I Application February 10, 1943, Serial No. 475,334
' In Sweden February 12, 1942 This invention relate to absorption refrigerating apparatus of the continuous cycle inert gas type including a gas bubble pump adapted during normal operation to efiect continuous circulation of absorption solution through the boiler and absorber.
The object of this invention is to provide a" method of and means for controlling the'operation of an absorption system of the above type.
Accordingv to the present invention the apps-- ratus includes an auxiliary liquid circulatin pump operable at will and adapted to convey absorption solution intended for-purposes other than absorption and in particular for effecting controlling operations during operation of said apparatus.
The invention includes a method of controlling the operation of absorption apparatus of the The invention will be hereinafter more 'fully described with reference to the accompanying drawing illustrating several embodiments or the invention'by way of example and in which:
Fig. l shows diagrammatically an absorption U refrigerating apparatus having a pump operative accordim to the invention,
Fig. .2 shows a diflerent means for starting the auxiliary pump. I
Rei'erring to Fig. 1, III designates the heating tube or flue of an absorption refrigerating apparatus working for example with water, hydrogen and ammonia. A tubular boiler ll connected in heat-conductive relation with the heating tube II, as by welding, communicates in known man- -ner with a riser pipe l2, and an air-cooled condenser l4, thence through a U-seal i8 with an evaporator II. The upper part 01' the evaporator. in the usual manner is formed as a room cooler and is provided with cooling line. The
lower coiled part serves for low temperature cooling suchasice-making. g
The gas mixture evolved in the evaporator passes through a gas heat exchanger l8, a conduit 28, to an absorber vessel and thence up- 56 v 10 Claims. -(Cl. 62-5) I 2 wardly through the, coil absorber IS in the usual manner back to the evaporator. Connected to the condenser i4 and the gas heat exchanger I8 is the usual pressure vessel 2| communicating through conduit 24 with the condensate conduit and through conduit 28 with the gas heat exchanger.
The solution degasifled in the boiler flows to the absorber coil I! through a liquid heat exchanger 22 and a conduit 86 andpasses from the absorber vessel 20 through the inner tube of the heat exchanger 22 to a pump tube. This pump is arrangedinheat-conductive connection 'with the heating tube so by spot welding points 8L. The manner' of operation of apparatus of this kind is well known and will not be described more fully herein,
According to the invention there is provided an auxiliary pum'p conduit 40 communicating for example with the lower part of, the boiler conduit I l. The pump conduit 40 terminates at its upper end in the pressure vessel 2!. This pump pumps the hot liquid from the boiler into the pressure vessel 2| and thence into the evaporator ll, which will cause rapid defrosting of the evaporator since the boiler liquid has a temperature varying between +130 and +180". The auxiliary pump 40 is heated by a heat transfer system,
preferably of the evaporating-condensing type.
This system consists of a collector 80 and a flexible tube 8|, such as a tombac tube, or any other flexible conduit, which communicates through a pipe socket 82 with a conduit 88, having a diameter large enough to prevent rising gas bubbles pumping the solution upwardly therethrough. From the lower end of the wide tube 83 extends a narrower U-tube 84 which, at 85, is
'connected in heat-conductive relation with the heating tube l0, preferably by welding. The rising leg or the U-tube 84 is. at 86, connected with the pump 40, and enters at 81 into the wide tube The collector is filled with a heattransferring agent ofa suitable kind. When this collector is raised, its content will flow through the flexible connection 8i into the wide tube 88 and into the 'U-tube 84. Here, the liquid owing to the heating zone 85 will boil or possibly be pumped upwardly so that the heat of the heating tube through condensation or the hot pumped solution will'be transferred at the contact zone 86 to the pump 40 which will thus be set in op eration. Since the heat transfer system, except 'for the collector and the flexible conduit 8|.
may be enclosed in the usual boiler insulation,
the heat losses will be very small during transfer of heat to the pump 40.
The vapours evolved at the contact point 85 will gradually condense at the coldest part 80 so that the system gradually boils dry due to collection of the transfer agent in the collector 80. During this time the system contains only vapour which insulates the pump 40 so that the heat transfer by conduction from the point 85 through the tube 84 to the point 86 is so small as to prevent further vapour expulsion in the As a filling for the system an agent is preferably chca'za which has a working pressure as low as possible relatively to that of the refrigerating apparatus. The starting of the pump 40 for defrosting action is in this case particularly simple,
. since it is only necessary to raise the collector 80 and then release the same to effect the defrosting operation, and if the auxiliary system is suitably filled, the operation of the pump 40 and therewith the defrosting process will cease automatically. By suitably forming the collector 80, for example-by increasing its surface by means of fins orother cooling elements, it is possible to hasten the initial condensation therein, thus also shortening the defrosting process. This will enable control to be effected without regulating devices, valves or other sensitive elements as hitherto used. The collector 80 may obviously be raised either manually or thermostatically, if desired through the intermediary of spring devices,
Fig. 2 shows another embodiment including an auxiliaryheat transfer system. The pump 40 is led through the interior of the auxiliary system which consists of a wide tube 90 in heat-conductive connection at 9i withthe heating tube ID. The collector 80 is connected to the wide tube 90 by means of the flexible conduit 8|. When the contents of the collector 80 by momentarily raising the latter are emptied into the wide tube 90,
denser element in communication with said larger conduit.
3. Absorption type refrigerating apparatus having a circuit for absorption liquid, a circulator for causing flow of absorption liquid in said circuit, a heat operated pump for raising absorption liquid upward in said system above said circuit, a source of heat, and an evaporating-condensin system constructed and arranged to transfer heat from said source to said pump.
4. Apparatus as set forth in claim 3 in which the condensing part of said evaporating-condensing system is formed by a flexibly mounted vessel.
5. Apparatus as set forth in claim 3 in which said evaporating-condensing system includes a conduit connected between the evaporating and condensing parts of the system and so constructed and arranged that liquid is caused to flow therethrough by vapor formed in said evaporating part, said conduit being'in heat transfer relation with said heat operated pump.
6.. Apparatus as set forth in claim 3 in which the condensing part of said evaporating-condensing system is formed by a flexibly mounted vessaid contents will vapourise adjacent the hot zone ill and condense in part on conduit 40, thus causing actuation of the pump until all vapour has again condensed in the collector 80. By means of a displaceable sleeve. on the collector 80 it is possible to regulate the proportion of vapour condensing in the pump 40 and'the collector 80, respectively. It is thus possible to ad- Just the defrosting period to any existing climatic conditions by displacing the sleeve.
As a heat transfer agent an aqueous solution of an anti-corrosive agent may be used, such as chromic acid alkaline salts. This will result in a relatively short heat-transfer period. If the system, however, contains aniline, for example, this will give long transfer periods. Also benzene, toluene, xylene and other cyclic hydrocarbons as well as many aliphatic hydrocarbons may be used as filling agents.
We claim:
1. A heat transfer system of the evaporatingcondensing p which include a vapourislng element in heat conductive relation with a rela-' tively hot zone, a higher located heat dissipating element in heat conductive relation with a relatively cold zone and a condensing member 10-" cated above the heat dissipating element.
2. A heat transfer system of the evaporatingcondensing type comprising a riser conduit adapted for vapour lift action and having a lower heat absorbing and a higher heat delivering portion, a conduit of larger cross sectional area connected to opposite ends of the riser conduit and a consel, and said evaporating-condensing system is enclosed by thermal insulation, said vessel being located outside of said insulation.
'7. An absorption refrigerating system includin a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift pump in said first solution circuit for lifting absorption solution to a point from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and said evaporator, a second vapor lift pump for lifting hot absorption solution from said second solution circuit to a point from whence said hot absorption solution flows by gravity into said evaporator, and a secondary heat transfer system associated with said generator for heating said second vapor lift pump.
8. An absorption refrigerating system includ-- ing a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift heating said second vapor lift pump, and means.
incorporated in said secondary heat transfer system whereby the operation of said system is manually initiated and automatically stopped after a predetermined time interval.
9. An absorption refrigerating system having a first solution circuit including a generator and an absorber, a vapor lift pump in said first solution circuit for lifting absorption solution into a part of said generator from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and an evaporator, a second vapor lift pump for lifting hot absorption solution in said second solution circuit to a point from whence said hot absorption solution ilows by gravity into said evaporator, a
secondary heat transfer system charged with avolatile fluid and having a heat receiving part associated with said generator, a heat transfer part associated with said second vapor lift pump, and a condensing part for storing said volatile fluid, the construction and arrangement of said secondary heat transfer system being such that said system is manually initiated and is autov matically stopped by collecting said volatile fluid in said condensing part.
10. An absorption refrigerating system including a generator, a condenser, an evaporator and an absorber, a refrigerant circuit including said generator, said condenser, said evaporator and said absorber, a first solution circuit including said generator and said absorber, a vapor lift pump in said first solution circuit for lifting absorption solution into. a part of said generator from whence said solution flows by gravity to said absorber, a second solution circuit including said generator and said evaporator, a second vapor lift pump in said second solution circuit for liftchamber, said fluid collecting chamber being arranged to collect substantially all of thevolatile fluid contained in said secondary heat transfer system to thereby render said system ineffective as a heat transfer system.
wnmm sagas KGGEL. mas ERIK wmm.
US475334A 1942-02-12 1943-02-10 Absorption refrigerating apparatus Expired - Lifetime US2402415A (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2581347A (en) * 1943-07-09 1952-01-08 Electrolux Ab Absorption refrigeration apparatus and heating arrangement therefor
US2631443A (en) * 1948-03-02 1953-03-17 Electrolux Ab Absorption refrigeration
US3776304A (en) * 1972-06-05 1973-12-04 Rca Corp Controllable heat pipe
US4099556A (en) * 1977-05-23 1978-07-11 Roberts Jr Charles C Variable thermal conductance reflux heat pipe
US4147206A (en) * 1977-06-17 1979-04-03 Hughes Aircraft Company Semi-active temperature control for heat pipe heat recovery units
US20120012282A1 (en) * 2007-05-15 2012-01-19 Asetek A/S Direct air contact liquid cooling system heat exchanger assembly

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2581347A (en) * 1943-07-09 1952-01-08 Electrolux Ab Absorption refrigeration apparatus and heating arrangement therefor
US2631443A (en) * 1948-03-02 1953-03-17 Electrolux Ab Absorption refrigeration
US3776304A (en) * 1972-06-05 1973-12-04 Rca Corp Controllable heat pipe
US4099556A (en) * 1977-05-23 1978-07-11 Roberts Jr Charles C Variable thermal conductance reflux heat pipe
US4147206A (en) * 1977-06-17 1979-04-03 Hughes Aircraft Company Semi-active temperature control for heat pipe heat recovery units
US20120012282A1 (en) * 2007-05-15 2012-01-19 Asetek A/S Direct air contact liquid cooling system heat exchanger assembly

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